Transceiver circuit employing shared digital signal processing circuitry for communicating radio frequency (RF) analog communications signals received by a remote unit in a wireless distribution system (WDS)

1. A transceiver circuit provided in at least one remote unit in a wireless distribution system (WDS), comprising: downlink digital signal processing circuitry having a predefined downlink digital signal processing bandwidth, the downlink digital signal processing circuitry comprising: a digital up-converter (DUG) configured to: receive a downlink digital communications signal comprising a first downlink digital baseband signal in a first downlink digital channel and a second downlink digital baseband signal in a second downlink digital channel; and generate an intermediate downlink digital communications signal comprising the first downlink digital baseband signal in a first selected downlink frequency and the second downlink digital baseband signal in a second selected downlink frequency; and a digital-to-analog converter (DAC) configured to receive and convert the intermediate downlink digital communications signal into a downlink analog communications signal comprising a first downlink analog signal in the first selected downlink frequency and a second downlink analog signal in the second selected downlink frequency; a first downlink analog signal path configured to: receive the downlink analog communications signal; and convert the first downlink analog signal into a first downlink analog radio frequency (RF) communications signal in a first downlink analog RF channel; and a second downlink analog signal path configured to: receive the downlink analog communications signal; and convert the second downlink analog signal into a second downlink analog RF communications signal in a second downlink analog RF channel; wherein the first downlink analog RF communications signal in the first downlink analog RF channel and the second downlink analog RF communications signal in the second downlink analog RF channel occupy a downlink RF spectrum wider than the predefined downlink digital signal processing bandwidth of the downlink digital signal processing circuitry.

2. The transceiver circuit of claim 1 , wherein the DUC is configured to receive the downlink digital communications signal comprising the first downlink digital baseband signal in the first downlink digital channel and the second downlink digital baseband signal in the second downlink digital channel that occupy a downlink digital spectrum narrower than the predefined downlink digital signal processing bandwidth of the downlink digital signal processing circuitry.

3. The transceiver circuit of claim 1 , further comprising a downlink signal splitter coupled to the DAC, the downlink signal splitter configured to: receive the downlink analog communications signal from the DAC; and provide the downlink analog communications signal to the first downlink analog signal path and the second downlink analog signal path.

4. The transceiver circuit of claim 3 , wherein the first downlink analog signal path comprises: a first downlink analog filter configured to receive the downlink analog communications signal from the downlink signal splitter and output the first downlink analog signal in the downlink analog communications signal; and a first up-conversion circuit configured to receive and convert the first downlink analog signal into the first downlink analog RF communications signal in the first downlink analog RF channel.

5. The transceiver circuit of claim 4 , wherein the first downlink analog signal path further comprises a first downlink power amplifier configured to receive and amplify the first downlink analog RF communications signal to a first specified downlink power level.

6. The transceiver circuit of claim 3 , wherein the second downlink analog signal path comprises: a second downlink analog filter configured to receive the downlink analog communications signal from the downlink signal splitter and output the second downlink analog signal in the downlink analog communications signal; and a second up-conversion circuit configured to receive and convert the second downlink analog signal into the second downlink analog RF communications signal in the second downlink analog RF channel.

7. The transceiver circuit of claim 6 , wherein the second downlink analog signal path further comprises a secondary downlink analog filter configured to attenuate unwanted RF elements in the second downlink analog RF communications signal.

8. The transceiver circuit of claim 7 , wherein the second downlink analog signal path further comprises a second downlink power amplifier configured to receive and amplify the second downlink analog RF communications signal to a second specified downlink power level.

9. The transceiver circuit of claim 1 , wherein: the intermediate downlink digital communications signal generated by the DUC comprises a downlink digital in-phase (I) element (I-element) and a downlink digital quadrature (Q) element (Q-element); and the DAC comprises an I-element DAC and a Q-element DAC, wherein: the I-element DAC is configured to convert the downlink digital I-element into a downlink analog I-element signal; and the Q-element DAC is configured to convert the downlink digital Q-element into a downlink analog Q-element signal.

10. The transceiver circuit of claim 9 , further comprising a downlink I/Q mixer configured to: receive the downlink analog I-element signal and the downlink analog Q-element signal from the I-element DAC and the Q-element DAC, respectively; and generate the downlink analog communications signal based on the downlink analog I-element signal and the downlink analog Q-element signal.

11. The transceiver circuit of claim 1 , further comprising a third downlink analog signal path configured to receive the downlink analog communications signal from the DAC and generate a third downlink analog RF communications signal.

12. The transceiver circuit of claim 1 , further comprising: a first uplink analog signal path configured to: receive a first uplink analog RF communications signal in a first uplink analog RF channel; and convert the first uplink analog RF communications signal into a first uplink analog signal in a first selected uplink frequency; a second uplink analog signal path configured to: receive a second uplink analog RF communications signal in a second uplink analog RF channel; and convert the second uplink analog RF communications signal into a second uplink analog signal in a second selected uplink frequency; a signal combiner configured to generate an uplink analog communications signal comprising the first uplink analog signal in the first selected uplink frequency and the second uplink analog signal in the second selected uplink frequency; and uplink digital signal processing circuitry having a predefined uplink digital signal processing bandwidth, the uplink digital signal processing circuitry comprising: an analog-to-digital converter (ADC) configured to receive and convert the uplink analog communications signal into an intermediate uplink digital communications signal comprising a first uplink digital baseband signal in the first selected uplink frequency and a second uplink digital baseband signal in the second selected uplink frequency; and a digital down-converter (DDC) configured to: receive the intermediate uplink digital communications signal from the ADC; and generate an uplink digital communications signal comprising the first uplink digital baseband signal in a first uplink digital channel and the second uplink digital baseband signal in a second uplink digital channel.

13. The transceiver circuit of claim 12 , wherein the DDC is configured to generate the uplink digital communications signal comprising the first uplink digital baseband signal in the first uplink digital channel and the second uplink digital baseband signal in the second uplink digital channel that occupy an uplink digital spectrum narrower than the predefined uplink digital signal processing bandwidth of the uplink digital signal processing circuitry.

14. The transceiver circuit of claim 12 , wherein the first uplink analog signal path and the second uplink analog signal path are respectively configured to receive the first uplink analog RF communications signal in the first uplink analog RF channel and the second uplink analog RF communications signal in the second uplink analog RF channel that occupy an uplink RF spectrum wider than the predefined uplink digital signal processing bandwidth of the uplink digital signal processing circuitry.

15. The transceiver circuit of claim 12 , wherein the first uplink analog signal path comprises: a first down-conversion circuit configured to receive and convert the first uplink analog RF communications signal into the first uplink analog signal in the first selected uplink frequency; and a first uplink analog filter configured to receive the first uplink analog signal from the first down-conversion circuit and output the first uplink analog signal to the signal combiner.

16. The transceiver circuit of claim 15 , wherein the first uplink analog signal path further comprises a first uplink power amplifier configured to receive and amplify the first uplink analog RF communications signal to a first specified uplink power level.

17. The transceiver circuit of claim 12 , wherein the second uplink analog signal path comprises: a second down-conversion circuit configured to receive and convert the second uplink analog RF communications signal into the second uplink analog signal in the second selected uplink frequency; and a second uplink analog filter configured to receive the second uplink analog signal from the second down-conversion circuit and output the second uplink analog signal to the signal combiner.

18. The transceiver circuit of claim 17 , wherein the second uplink analog signal path further comprises a secondary uplink analog filter configured to attenuate unwanted RF elements in the second uplink analog RF communications signal.

19. The transceiver circuit of claim 18 , wherein the second uplink analog signal path further comprises a second uplink power amplifier configured to receive and amplify the second uplink analog RF communications signal to a second specified uplink power level.

20. The transceiver circuit of claim 12 , further comprising an uplink in-phase (I) and quadrature (Q) (I/Q) mixer configured to: receive the uplink analog communications signal; and generate an uplink analog I-element signal and an uplink analog Q-element signal based on the uplink analog communications signal.

21. The transceiver circuit of claim 20 , wherein: the intermediate uplink digital communications signal comprises an uplink I-element and an uplink Q-element; and the ADC comprises an I-element ADC and a Q-element ADC, wherein: the I-element ADC is configured to receive and convert the uplink analog I-element signal into the uplink I-element in the intermediate uplink digital communications signal; and the Q-element ADC is configured to receive and convert the uplink analog Q-element signal into the uplink Q-element in the intermediate uplink digital communications signal.

22. The transceiver circuit of claim 12 , further comprising a third uplink analog signal path configured to receive a third uplink analog RF communications signal and provide a third uplink analog signal to the signal combiner.